Sensors and Materials, Vol. 29, No. 4 (2017) 491 496 MYU Tokyo 491 S & M 1342 Wideband Coupled Loop Antenna for Laptop PC Sensor Network Applications Chien-Min Cheng, Shih-Hsien Tseng, and Wen-Shan Chen * Department of Electronic Engineering, Southern Taiwan University of Science and Technology, No. 1, Nan-Tai Street, Yungkang Dist., Tainan City 710, Taiwan (Received September 30, 2016; accepted Junuary 6, 2017) Keywords: loop antenna, laptop device, envelope correlation coefficient In this paper, we propose a low-profile and small wideband multiple-input multiple-output (MIMO) antenna for laptop device sensor network applications, which includes long term evolution (LTE)/wireless wide area network (WWAN) bands, where operating frequencies are 698 960 and 1710 2690 MHz. The proposed antenna is composed of two subantenns: a monopole antenna and a coupled loop antenna. The proposed antenna has dimensions of 62.8 11.8 0.4 mm 3, good antenna impedance bandwidth, nearly omnidirectional radiation patterns, antenna isolation of 15 db, and an ECC value of only 0.01. Thus, it is very suitable for the sensor network applications of small LTE/WWAN band laptop devices, including modern commercial LTE (700/2300/2500), WWAN (850/900), process control system (PCS), distributed control system (DCS), and universal mobile tellecommunications system (UMTS) standards. 1. Introduction Owing to the tendency to miniaturize of modern electronic devices, laptop antennas are also following the trend of small size and wideband for wider applications, and this has become a challenge to laptop antenna designers. Recently, the dominant operating bands of the most popular laptop devices have been the long term evolution (LTE)/wireless wide area network (WWAN), which operates for 2G, 3G, and 4G applications. (1 3) The operating bands of LTE include 698 960, 1710 2690, and 3400 3800 MHz. For the GSM850/900, distributed control system (DCS), process control system (PCS), and universal mobile tellecommunications system (UMTS) standards, the operating bands are 824 960 and 1710 2170 MHz. (3 6) Hence, most laptop devices include two main wide operating bands of 698 960 and 1710 2690 MHz. (7,8) The main design concepts of modern laptop devices are the planar inverted-f antenna (PIFA) and the coupling loop, owing to their simple structures, which reveal better impedance bandwidths as well as antenna properties. Furthermore, compared to normal antennas (single input and single output), the multiple-input multiple-output (MIMO) antennas enhance data transmission capacities and rates owing to their multi-inputs and multi-outputs; therefore, this has recently become the most widely used communication technology. In this paper, using the MIMO antenna design technology, we propose two coupling loop subantennas (Antenna_1 and Antenna_2) to resonate lower and upper bands (698 960 and 1710 * Corresponding author: e-mail: ccmin523@gmail.com http://dx.doi.org/10.18494/sam.2017.1531 ISSN 0914-4935 MYU K.K.
492 Sensors and Materials, Vol. 29, No. 4 (2017) 2690 MHz), which thus can cover the operating bands of LTE/WWAN for laptop devices. (9 11) Because impedance bandwidth, isolation, and envelope correlation coefficient (ECC) are important and practical design parameters for laptop devices, we present and investigate these parameters in this study. Finally, antenna peak gains and efficiencies are also presented and analyzed. 2. Antenna Design The proposed antenna was designed on FR4 substrates (thickness = 0.4 mm, ε r = 4.4) using a 50-Ω coaxial line to feed to a metal ground (166 120 mm 2 ). Except for the main antenna pattern, additional metal (thickness = 3 mm) was added to form a three-dimensional structure. Detailed design patterns and parameters are shown and listed in Figs. 1 and 2 and Table 1. The proposed antenna can be divided into two subantennas with the same dimensions and symmetric structure: Antenna_1 (monopole antenna) and Antenna_2 (loop antenna). In addition, Antenna_1 is the Fig. 1. Geometry of the proposed laptop antenna. Fig. 2. Detailed structure of Antenna_1. Table 1 Design parameters of Antenna_1 (unit: mm). A B C D E F G H I J K L M N O P Q 62.8 21.3 2.6 11.8 20.7 0.7 10.7 6 44.4 2 1.5 22.2 4.8 1 1.85 0.5 3
Sensors and Materials, Vol. 29, No. 4 (2017) 493 main radiation monopole antenna composed of two inverted-l structures, which resonate and cover the upper band of 1710 2690 MHz. However, Antenna_2 is a loop antenna excited by the main radiation pattern and mutual coupling with another inverted-l antenna to the ground plane for better impedance matching and enabling it to resonate and cover the lower band of 698 960 MHz. The simulation results were obtained using the HFSS simulator, the measured results of the proposed antenna were obtained from the network analyzer, and far-field measurements including the efficiencies and peak gains were completed using the SATIMO system in a chamber. 3. Results and Discussion The simulated and measured S 11 (for Antenna_1) and S 22 (for Antenna_2) are shown in Fig. 3; the 6 db dashed line for laptop antenna design is also presented. It can be seen that the proposed wideband antenna can cover both lower (698 960 MHz) and upper (1710 2690 MHz) bands of LTE/WWAN. We also found that the simulated and measured return losses reveal a slight mismatch for both lower and upper bands because of the existence of parasitic capacitance, which causes shifts in these two operating bands. As the distance between Antenna_1 and Antenna_2 is 4 cm, the isolation is as shown in Fig. 4. It can be observed that for both lower and upper bands, owing to the back-to-back structure of these two subantennas, the proposed antenna reveals very good isolation (< 15 db). Hence, the proposed antenna possesses good isolation for reducing the mutual interference between these two subantennas. From the ECC shown in Fig. 5, it can be seen that, from 698 to 2700 MHz, all the ECC values were very stable and varied only between 0.025 and 0.035. Because of the smaller than 0.01 ECC value variations between Antenna_1 and Antenna_2, an improvement in the 4G channel capacity of the proposed antenna can be achieved easily. Figure 6 shows the 2D radiation patterns measured at 700, 1800, and 2600 MHz for the XY plane (azimuthal plane), XZ plane (elevation plane orthogonal to the device ground plane), and YZ plane (elevation plane parallel to the device ground plane), respectively. For a low frequency of 700 MHz, the antenna reveals a nearly omnidirectional Fig. 3. Simulated and measured S 11 of Antenna_1 and S 22 of Antenna_2. Fig. 4. Measured and simulated isolation between Antenna_1 and Antenna_2 (distance is 4 cm).
494 Sensors and Materials, Vol. 29, No. 4 (2017) (a) Fig. 5. Measured envelope correlation coefficient. (b) (c) Fig. 6. Measured radiation patterns for the LTE/ WWAN coupled loop antenna. (a) 700, (b) 1800, and (c) 2600 MHz. radiation pattern in the XY plane, which achieves good total radiated power (TRP) and total isotropic sensitivity (TIS), and better transmission and reception can be obtained for the laptop PC applications. Furthermore, for the XY plane at 1800 and 2600 MHz, variations of the radiation patterns can be found, which can be applied to the complicated propagation environment. The simulated and measured far-field characteristics were determined using the SATIMO system in a chamber, such as antenna efficiencies (shown in Fig. 7) and peak gains (shown in Fig. 8). The lower and upper band efficiencies were 45 60 and 43 63%, and 48 82 and 46 72% for Antenna_1 and Antenna_2, respectively. Furthermore, the lower and upper band peak gains were 0.3 2.8 and 2.3 5.2 dbi, and 0.1 2.7 and 1.8 5.5 dbi for Antenna_1 and Antenna_2, respectively. These antenna characteristics are acceptable for modern applications, and for 4G fast data transmission, the antenna can increase channel capacity owing to its small variation in the ECC value. A photograph of part of the proposed antenna (Antenna_2) is presented in Fig. 9, which has miniaturized dimensions of only 62.8 11.8 mm 2.
Sensors and Materials, Vol. 29, No. 4 (2017) 495 Fig. 7. Measured efficiencies of Antenna_1 and Antenna_2. Fig. 8. Measured peak gains of Antenna_1 and Antenna_2. Fig. 9. Photograph of Antenna_2. 4. Conclusions In this paper, a low-profile wideband coupling loop MIMO antenna for laptop device sensor network applications was presented that can cover modern LTE/WWAN bands of 698 960 MHz and 1710 2690 MHz. The proposed antenna has miniaturized dimensions of 62.8 11.8 0.4 mm 3, good antenna impedance bandwidth, nearly omnidirectional radiation patterns, antenna isolation of 15 db, and an ECC value of only 0.01. The optimal antenna peak gain is 4.77dBi and the antenna efficiency is 79%; thus, the proposed antenna is very suitable for the sensor network applications of small LTE/WWAN band laptop devices. Acknowledgements This work was kindly supported by the Ministry of Science and Technology of the Republic of China (MOST 105-2221-E-218-034 and 105-ET-E-218-001-ET). References 1 C. T. Lee and K. L. Wong: IEEE Trans. Antennas Propag. 58 (2015) 2479. 2 S. C. Chen and K. L. Wong: Microwave Opt. Technol. Lett. 52 (2010) 2059. 3 J. Villanen, J. Ollikainen, O. Kivekas, and P. Vainikainen: 2003 IEEE 58th Vehicular Technol. Conf. (VTC- 2003-Fall) p. 40.
496 Sensors and Materials, Vol. 29, No. 4 (2017) 4 R. A. Bhatti, J. H. Choi, and S. O. Park: IEEE Antennas Wirel. Propag. Lett. 8 (2009) 129. 5 V. Plicanic, B. K. Lau, A. Derneryd, and Z. Ying: IEEE Trans. Antennas Propag. 57 (2009) 1547. 6 C. Tse and K. L. Wong: IEEE Trans. Antennas Propag. 58 (2010) 2479. 7 S. H. Chang and W. J. Liao: Int. Symp. Antennas Propag. (IEEE, 2012) p. 142. 8 A. Krewski, W. L. Schroeder, and K. Solbach: Int. Symp. Antennas Propag. (IEEE, 2012) p. 1894. 9 S. C. Chen and J. Y. Sze: Int. Symp. Antennas Propag. (IEEE, 2014) p. 425. 10 P. W. Lin, T. J. Wu, and K. L. Wong: Int. Symp. Antennas Propag. (IEEE, 2013) p. 514. 11 X. Zhu and Y. Sun: Prog. Electromagn. Res. C 42 (2013) 229. About Authors Chien-Min Cheng received his B.S., M.S., and Ph.D. degrees from the National Taiwan Ocean University, National Cheng Kung University, and National Sun Yat-Sen University, Taiwan, in 1984, 1990, and 2008, respectively. From 2009 to 2012, he was an associate professor at Southern Taiwan University of Science and Technology, Taiwan. Since 2013, he has been a professor at the same university. His research interests are in electronic ceramics, thin films, microwave device design, and piezoelectric ceramics. Shih-Hsien Tseng received his B.S. degree from Kao Yuan University and M.S. degree from Southern Taiwan University of Science and Technology. He is currently pursuing his Ph.D. degree at Southern Taiwan University of Science and Technology. His research interests are in electronic ceramics, microwave device design, and antenna design. Wen-Shan Chen received his B.S. degree from National Taiwan University of Science and Technology and his Ph.D. degree from National Sun Yat-Sen University, Taiwan, in 2001. He is currently a Professor of Southern Taiwan University of Science and Technology. He is an IEEE Senior Member with AP, MTT, and EMC Societies. He served as the General Secretary in 2007 2008, Vice Chair in 2009 1010, and Chair in 2011 2012, all for the IEEE AP-S Tainan Chapter. He is also a consultant for the IEEE AP-S Tainan Chapter. He is a member of the Institute of Antenna Engineers of Taiwan and was elected to be an AdCom member in 2008 2015. He is a member of the Chinese Microwave Association and was elected to be an AdCom member in 2015 2016. He is a member of the TIEEE, Chinese Institute of Electrical Engineering, and IEICE. His research interests include antenna design, RF, and microwave circuits.